Krypton difluoride

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Krypton difluoride

Skeletal formula of krypton difluoride with a dimension Spacefill model of krypton difluoride
Names
IUPAC name Krypton(II) fluoride
Other names Krypton fluoride
Identifiers
CAS Number	13773-81-4 N
ChemSpider	75543 Y
Jmol 3D model	Interactive image
PubChem	83721
InChI InChI=1S/F2Kr/c1-3-2 Y Key: QGOSZQZQVQAYFS-UHFFFAOYSA-N Y InChI=1/F2Kr/c1-3-2 Key: QGOSZQZQVQAYFS-UHFFFAOYAJ
SMILES F[Kr]F
Properties
Chemical formula	F2Kr
Molar mass	121.79 g·mol−1
Appearance	Colourless crystals (solid)
Density	3.24 g cm−3 (solid)
Solubility in water	Reacts
Structure
Crystal structure	Body-centered tetragonal[1]
Space group	P42/mnm, No. 136
Lattice constant	a = 0.4585 nm, c = 0.5827 nm
Molecular shape	Linear
Dipole moment	0 D
Related compounds
Related compounds	Xenon difluoride
Except where otherwise noted, data are given for materials in their standard state (at 25 °C [77 °F], 100 kPa).
N verify (what is YN ?)
Infobox references

Krypton difluoride, KrF₂ is a chemical compound of krypton and fluorine. It was the first compound of krypton discovered.^[2] It is a volatile, colourless solid. The structure of the KrF₂ molecule is linear, with Kr−F distances of 188.9 pm. It reacts with strong Lewis acids to form salts of the KrF⁺ and Kr
₂F⁺
₃ cations.^[3]

Synthesis

Krypton difluoride can be synthesized using many different methods including electrical discharge, photochemical, hot wire, and proton bombardment. It can also be prepared by irradiating krypton with ultraviolet rays in a fluorine-argon gas mixture at -265 degrees. The product can be stored at −78 °C without decomposition.^[4]

Electrical discharge

The first method used to make krypton difluoride and the only one ever reported to produce krypton tetrafluoride (although the identification of krypton tetrafluoride was later shown to be mistaken) was the electrical discharge method. The electrical discharge method involves having 1:1 to 2:1 mixtures of F₂ to Kr at a pressure of 40 to 60 torr and then arcing large amounts of energy between it. Rates of almost 0.25 g/h can be achieved. The problem with this method is that it is unreliable with respect to yield.^[3][5]

Proton bombardment

Using proton bombardment for the production of KrF₂ has a maximum production rate of about 1 g/h. This is achieved by bombarding mixtures of Kr and F₂ with a proton beam that is operating at an energy level of 10 MeV and at a temperature of about 133 K. It is a fast method of producing relatively large amounts of KrF₂, but requires a source of α-particles which usually would come from a cyclotron.^[3][6]

Photochemical

The photochemical process for the production of KrF₂ involves the use of UV light and can produce under ideal circumstances 1.22 g/h. The ideal wavelengths to use are in the range of 303–313 nm. Harder UV radiation is detrimental to the production of KrF₂. Using Pyrex glass or Vycor or quartz will significantly increase yield because they all block harder UV light. In a series of experiments performed by S. A Kinkead et al., it was shown that a quartz insert (UV cut off of 170 nm) produced on average 158 mg/h, Vycor 7913 (UV cut off of 210 nm) produced on average 204 mg/h and Pyrex 7740 (UV cut off of 280 nm) produced on average 507 mg/h. It is clear from these results that higher energy ultra violet light reduces the yield significantly. The ideal circumstances for the production KrF₂ by a photochemical process appear to occur when krypton is a solid and fluorine is a liquid which occur at 77K. The biggest problem with this method is that it requires the handling of liquid F₂ and the potential of it being released if it becomes over pressurized.^[3][5]

Hot wire

The hot wire method for the production of KrF₂ uses krypton in a solid state with a hot wire running a few centimeters away from it as fluorine gas is then run past the wire. The wire has a large current, causing it to reach temperatures around 680 °C. This causes the fluorine gas to split into its radicals which then can react with the solid krypton. Under ideal conditions, it has been known to reach a maximum yield of 6 g/h. In order to achieve optimal yields the gap between the wire and the solid krypton should be 1 cm, giving rise to a temperature gradient of about 900 °C/cm. The only major downside to this method is the amount of electricity that has to be passed through the wire thus making it dangerous if not properly set up.^[3][5]

Structure

Krypton difluoride can exist in one of two possible crystallographic morphologies: α-phase and β-phase. β-KrF₂ generally exists at above −80 °C, while the α-KrF₂ is more stable at lower temperatures.^[3] The unit cell of α-KrF₂ is body-centred tetragonal.

Chemistry

Krypton difluoride is primarily a powerful oxidising and fluorinating agent: for example, it can oxidise gold to its highest-known oxidation state, +5. It is more powerful even than elemental fluorine due to the reduced bond F-F to Kr-F with redox potential of 3.5, making it the most powerful known oxidising agent, though KrF
₄ could be even stronger:^[7]

7 KrF
₂ (g) + 2 Au (s) → 2 KrF⁺
AuF⁻
₆ (s) + 5 Kr (g)

KrF⁺
AuF⁻
₆ decomposes at 60 °C into gold(V) fluoride and krypton and fluorine gases:^[8]

KrF⁺
AuF⁻
₆ → AuF
₅ (s) + Kr (g) + F
₂ (g)

KrF
₂ can also directly oxidise xenon to xenon hexafluoride:^[7]

3 KrF
₂ + Xe → XeF
₆ + 3 Kr

KrF
₂ is used to synthesize the highly reactive BrF⁺
₆ cation.^[4] KrF
₂ reacts with SbF
₅ to form the salt KrF⁺
SbF⁻
₆; the KrF⁺
cation is capable of oxidising both BrF
₅ and ClF
₅ to BrF⁺
₆ and ClF⁺
₆, respectively.^[9]

KrF
₂ is able to oxidise silver to its +3 oxidation state, reacting with elemental silver or with AgF to produce AgF
₃.^{[10] [11]}

Related compounds

• Xenon difluoride, XeF₂

References

General reading

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External links

• NIST Chemistry WebBook: krypton difluoride